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Social proximities of developing gorilla males (Gorillagorilla gorilla) in European zoos
Benoît Létang, Baptiste Mulot, Vanessa Alerte, Thomas Bionda, Lisa Britton,Tjerk Ter, Janos Szantho, Jean-Pascal Guéry, Cedric Sueur
To cite this version:Benoît Létang, Baptiste Mulot, Vanessa Alerte, Thomas Bionda, Lisa Britton, et al.. Social proximitiesof developing gorilla males (Gorilla gorilla gorilla) in European zoos. Applied Animal BehaviourScience, Elsevier, 2020, pp.105175. 10.1016/j.applanim.2020.105175. hal-03035093
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Social proximities of developing gorilla males (Gorilla gorilla gorilla) in European zoos: 1
the consequences of castration and social composition. 2
Benoit Létang 1, 2
, Baptiste Mulot 3, Vanessa Alerte
4, Thomas Bionda
5, Lisa Britton
6, Tjerk 3
ter Meulen 7, János Szánthó
8 , Jean-Pascal Guéry
2*, and Cédric Sueur
1,9*. 4
Benoit Létang: main author; email address: [email protected] ; telephone number: +33(0)626146041; 5 ORCID number: 0000-0002-8997-0702. 6 * These two authors equally supervised the study. 7
1 Université de Strasbourg, CNRS, IPHC UMR 7178, F-67000 Strasbourg, France.
8
2 Zoological institution “La Vallée des Singes”, Le Gureau, 86700 Romagne, France.
9
3 Zoological institution “Zooparc de Beauval” & Association “Beauval Nature”, 41110, Saint-Aignan, France. 10
4 Zoological institution “Parc zoologique d’Amnéville”, 1 rue du Tigre, 57300, Amnéville, France.
11
5 Zoological institution “Apenheul”, J.C. Wilslaan 21, 7313 HK Apeldoorn, the Netherlands. 12
6 Zoological Institution “Chessington World of Adventures”, Leatherhead Rd, Chessington KT9 2NE, UK.
13 7 Zoological Institution “GaïaZoo”, Dentgenbachweg 105, 6468 PG Kerkrade, the Netherlands. 14
8 Zoological institution “Artis Amsterdam Royal zoo”, Plantage Kerklaan 38-40, 1018 CZ Amsterdam, the 15
Netherlands. 16 9 Institut Universitaire de France, Paris, France 17
Abstract 18
In the European captive population of western lowland gorillas (Gorilla gorilla gorilla), the 19
harem social structure and an even sex ratio at birth result in a surplus of males and 20
consequent management difficulties. This study seeks to assess the socialization differences 21
between captive juvenile and adolescent male gorillas according to their fertility status (intact 22
vs castrated) in different social compositions (familial vs bachelor groups), and to evaluate the 23
suitability of castration as a management tool for the EEP gorilla population. We carried out 24
social network analyses (SNA) to assess the “positive” proximity pattern of behaviour in 93 25
western lowland gorillas aged from 0 to 45 years old and housed in 11 social units (seven 26
familial and four bachelor groups). We compared the data recorded for the 27 juvenile and 27
adolescent (i.e. subadult and blackback) males included in our sample size. Although no 28
differences were revealed between the intact juveniles and the castrated juveniles living in 29
familial groups, our results showed that castrated adolescent individuals showed more 30
cohesiveness within their familial group than their intact conspecifics in terms of their activity 31
budget. They also displayed a “positive” proximity pattern of behaviour with all group 32
*Revised Manuscript (Clean version)Click here to view linked References
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members, including adults (silverback and females). Despite being significantly more 1
isolated, the intact adolescent males living in bachelor groups do not differ from their 2
castrated and intact counterparts of the same age class living in familial groups in terms of 3
their strength of “positive” behaviour when close to group conspecifics. This effect highlights 4
the social benefits of male-male interactions within gorilla species. Our results may be 5
evidence that both of the management strategies compared here, i.e. bachelor groups and 6
castration, could be appropriate socio-behavioural enrichments during juvenility and 7
adolescence. These findings also highlight the need to continue investigations until the study 8
subjects reach adulthood to validate and/or improve these tools for the welfare-compliant 9
management of gorilla male surplus in captivity. 10
11
Keywords: Gorillas, castration, bachelor, maturation, social network analysis, welfare. 12
13
Introduction 14
At the beginning of 2016, the EAZA (European Association of Zoos and Aquaria) ex-15
situ programme for gorillas (GEEP) comprised a total population of over 475 individuals in 16
74 institutions. Zoos have become successful in breeding western lowland gorillas, and they 17
have considerably improved the captive management of this species over the years by sharing 18
experience and knowledge that can help to improve daily husbandry (Ogden & Wharton, 19
1997; Stoinski et al., 2001; Strong et al., 2017). 20
However, the balanced sex ratio that naturally occurs at birth for this species and the 21
long life of breeding males in captivity result in a problem of surplus males (Stoinski et al, 22
2013; Vermeer & Devreese, 2015; Vermeer et al., 2014). This male overpopulation has been 23
managed by the creation of bachelor gorilla groups in zoos over the last three decades, namely 24
through the application of previously published knowledge of wild mountain gorillas 25
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(Johnstone-Scott, 1988; Pullen, 2005; Watts & Meder, 1996). Several factors including age, 1
early familiarity of individuals, group composition, number of males, exhibit design, rearing 2
experience and personality have already been identified as possible elements that play roles in 3
the successful formation and maintenance of captive multi-male gorilla groups (Coe, Scott, & 4
Lukas, 2009; Gold & Maple, 1994; Kuhar, Stoinski, Lukas, & Maple, 2006; Pullen, 2005; T. 5
S. Stoinski, Lukas, Kuhar, & Maple, 2004). In the European region, twenty gorilla bachelor 6
groups were established in 17 institutions between 1995 and 2015. A backward analysis of the 7
last two decades of bachelor group management in European institutions highlights social 8
instabilities that could be dangerous over time, such as aggressions and injuries. However, 9
recent studies on the North American captive gorilla population reported similar rates of 10
contact aggression shown by males in both familial and bachelor housing conditions. The 11
influence of young silverbacks was a strong confounding factor that increased both agonistic 12
behaviour and the wounding rate in the bachelor groups (Leeds et al., 2015; Stoinski et al., 13
2013). These authors concluded that all-male groups could therefore be a long-term housing 14
strategy offering male gorillas the benefits of socialization if appropriate social grouping 15
prevents the risk of escalated aggression and the maintenance of affiliative relationships. As 16
early as 2001, the zoo community emphasized the importance of describing and studying how 17
adolescent blackback males or young silverback males change their social relationships with 18
the dominant silverback male as they grow older (Nakamichi & Kato, 2001). Indeed, key 19
predictors of social instability must be identified to prevent severe aggressive outbreaks in 20
bachelor groups when bachelor males become silverbacks. Likewise, knowledge of key social 21
stability predictors is also necessary to ensure that the affiliative relationships of young 22
individuals are maintained throughout maturation until adulthood. While our knowledge of 23
instability indicators for post-adolescent males and young silverbacks is increasing, very few 24
studies to date have investigated the stability indicators emerging from data collected on 25
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younger individuals (juveniles and adolescents). Yet this information could be of crucial 1
importance to guide management decisions attempting to control captive male 2
overpopulation. 3
However, this bachelor group management strategy may not be sufficient to ensure the long-4
term relocation of future surplus males. The solutions that have been proposed and discussed 5
include the use of sex ratio selection, a promising approach that requires further improvement. 6
The Gorilla EEP (GEEP) has already reduced the number of females per breeding male to 7
current levels of 2 or 3 at the most, thus providing a normal social upbringing for the 8
offspring. Another proposal is to extend the time that young males remain in their natal group, 9
or house them alone. This also appears to be impossible: blackback sub-adult transition is 10
driven by intra-group competition, generally through unidirectional aggression exhibited by 11
the silverback (Robbins, 2007), so remaining longer in their familial group will directly 12
impact their well-being. It also appears unethical to house males alone in zoos, because this 13
solution could impact individual welfare with more self-harming or abnormal behaviours such 14
as hair plucking, regurgitation and reingestion, as reported for gorillas housed alone (Less et 15
al., 2013). Although the use of euthanasia as a population management strategy would free up 16
hosting capacities that could be used for housing other gorillas, this strategy is not 17
recommended by the Great Ape TAG (Taxon Advisor Group), who limit its use to 18
exceptional circumstances: “The Great Ape TAG accepts use of euthanasia for Great Apes in 19
preference to keeping them long term under conditions which significantly reduce the 20
individuals’ welfare, and if there is no other alternative” (Abelló, Bemment, & Rietkerk, 2017 21
page 102). Castration meets this criteria (see Moreno Rivas and colleagues (2018) for 22
additional explanations of the benefits of castration, such as improving genetic variability or 23
reducing the potential drastic negative demographic effects due to an overuse of females 24
contraception), and also reduces the cost of accommodation structures for this species. Given 25
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the expense of creating new facilities for big mammals like gorillas, keeping the castrated 1
individuals in their familial group would also have financial advantages. For all these reasons, 2
the Gorilla EEP agreed to test the use of castration among males that were genetically over-3
represented in the population as a supplementary tool to complement other, insufficient 4
management strategies. Castration at an early age is a possible management strategy insofar 5
that mature castrated males can remain in the presence of the silverback male in their native 6
familial group without the risk of conflicts, or can form part of a bachelor group without 7
competing for dominance. This study is a first step in this new EEP management strategy, and 8
focuses on young gorillas in a familial housing situation to observe their social development. 9
Until 2011, there was only one castrated gorilla in the GEEP and he is the only recorded 10
castrated individual to have reached adulthood. The reports collected from caretakers reveal 11
that this male had a good quality of life (both in the nursery and in the social group). Given 12
this positive feedback, the GEEP committee recommended the castration of ten immature 13
males living in familial groups between 2007 and 2016, followed by a regular monitoring of 14
their development and careful observation to identify any possible impact on the physical, 15
psychological and behavioural development of these males and of the other members of their 16
familial group. 17
This study investigates the effect of such castration on immature male gorillas. Social 18
behaviour changes dramatically during primate adolescence, and it is unknown how far 19
adolescent social behavioural development is reliant on testosterone and other gonadal 20
hormones (Richards et al., 2009). In western lowland gorillas, these behavioural and 21
hormonal changes mainly occur during juvenescence (from 3-4 years to 6-7.5 years) and 22
adolescence (from 6-7.5 years to 12-14 years), and continue until they reach adulthood as 23
young silverbacks (from 12-14 years to 18-20 years) (Breuer et al., 2009; Stoinski et al., 24
2002). It is therefore important to improve our knowledge of how castration effects 25
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individuals during these life stages. 1
Zoos do not base their gorilla husbandry decisions in zoos on the physiological and 2
nutritional needs of gorillas alone; they also take the fundamental social needs of this species 3
into account in order to ensure acceptable levels of welfare. We define the socialization 4
process as the acquisition of a social repertoire and the construction of a social network during 5
growth. It is essential to understand the important role that social environment plays in an 6
individual’s health and how the management of different social housing situations can 7
improve individual health and welfare (Rose & Croft, 2015; Sueur & Pelé, 2015). These 8
criteria are vital welfare clues to ensure the provision of optimal care and govern the 9
management of surplus males in the captive Gorilla EEP population. 10
More recently, social network analysis (SNA) has been proved to be an efficient tool for 11
the management of zoo animals (McCowan et al., 2008; Sueur et al., 2011), as reviewed by 12
Rose and Croft in 2015, and is increasingly used in this domain. In 2011, a social network 13
analysis of social preferences in a captive chimpanzee community (Clark, 2011) supported the 14
hypothesis that a large and modern exhibit facilitates the expression of social preferences 15
among individuals. The same year, captive chimpanzees with a high social status were shown 16
to occupy central positions in the grooming network (Kanngiesser et al., 2011). This 17
highlighting of the pivotal role played by specific individuals in maintaining cohesiveness 18
could influence how zoos manage the restructuring of groups. The use of SNA may provide 19
valuable information about the different social life stages in intact or castrated immature 20
gorilla males living in familial and bachelor captive social groups. 21
Our study seeks to understand the social differences experienced by castrated and intact 22
individuals living in different social situations - namely familial and bachelor - from the 23
juvenescent to the adolescent maturity phases. Our study hypothesises that these immature 24
captive gorilla males should all show different behavioural types or strategies, depending on 25
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their social housing and their age. Publications describing captive and wild populations report 1
that intact males emigrated from the familial groups following their gradual peripheralization 2
and a decrease in the number and quality of relationships they had with other group members, 3
particularly the silverback (Abelló et al., 2017; Harcourt, 1978; Harcourt & Stewart, 2007; 4
Harcourt & Stewart, 1977). In contrast, the weaker expected physical development of 5
castrated males on reaching adulthood could facilitate their relationships with younger group 6
members. Maturing intact gorillas that live in bachelor groups instead of living alone could 7
also benefit from the experience of silverbacks (Levréro et al., 2006). We therefore make the 8
following hypotheses: 1) For intact males living in familial groups, positive social interactions 9
will decrease with age; 2) For castrated males living in familial groups, positive social 10
interactions will remain stable or increase; therefore 3) An increase will probably be 11
observed in the number and quality of relationships between castrated immature males and 12
adult conspecifics in familial groups; and finally 4) Significantly more numerous positive 13
social interactions will be observed for intact males living in bachelor groups than for intact 14
males living in familial groups. 15
Methods 16
This research project was designed in accordance with the best practices and highest 17
ethical standards, and meets national and international legislation requirements. Moreover, all 18
methods comply with the EAZA Code of Ethics (www.eaza.net) and the WAZA Code of 19
Ethics and Animal Welfare, namely the ‘Ethical Guidelines for the Conduct of Research on 20
Animals by Zoos and Aquaria’ (www.waza.org). 21
Subjects and housing 22
Small sample size is a common cause of difficulty in many studies seeking to carry out 23
long-term monitoring of socialization processes in captive animals (Watters et al, 2009). Our 24
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study addresses this problem through the observation of 93 western lowland gorillas (51 1
males and 42 females) living in eleven different social units (seven familial groups and four 2
bachelor groups) located in nine different zoological institutions; each group was studied for 3
approximately one month (see Table 1 for full details). Individuals between 0-3 years of age 4
were classified as infants (INF), juveniles (JUV) of both sexes were aged between 3-6 years, 5
and adolescents (ADO) were 6-10 years old for females and 6-12 years old for males. 6
Females were considered adults (A) at 10 years of age, and males were considered adults at 7
the age of 18 after a transitory young silverback (YSB) age class from the age of 12 to 18. All 8
the groups had daily access to naturalistic outdoor enclosures or islands measuring between 9
400 and 10 000 square meters in addition to their indoor areas. All the different environments 10
were equipped with appropriate permanent and temporary enrichment for these animals. The 11
housing in all the institutions concerned is accredited under the same Gorilla EEP standards 12
(Abelló et al., 2017, section 2, pages 32 to 51). All of the 10 castrated immature gorillas 13
present in our study were castrated by surgery before the age of three, and a minimum of 6 14
months before the observations began. 15
Data collection 16
BL collected all data for each group over approximately one month between April 2016 17
and May 2017 (see Table 1). Observations were carried out from 9:00 a.m. to 5:00 p.m, when 18
some of the groups observed solely had access to their outside enclosure and the others were 19
free to move between the inside and outside enclosures according to group management and 20
weather conditions. Individuals in the infant age class (0-3 years old) were not included in 21
observation data because they were still dependent on their mothers. 22
We defined “social preference proximity” as a spatial association within one meter of the 23
focal individual, with or without contact, and the “social tolerance proximity” as distances of 24
one to five meters between the focal individual and a conspecific. The sum of social 25
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preference and tolerance proximities provides the “general social proximity” spatial 1
associations (within five meters of the focal individual). 2
Depending on the number of individuals per group, observations were made using two to 3
four 10-minute continuous focal animal samplings per day for each group member. We 4
recorded proximities between individuals but excluded those relating to aggressions, thus 5
retaining proximities that occurred during affiliative or neutral behaviours (see Table S1) in 6
order to solely interpret data that are collected in a context of “positive” welfare and 7
comparable for all groups. When a focal individual was in the proximity of more than one 8
conspecific, the observer recorded the number of individuals and the exact duration whenever 9
the perimeters of each individual changed (from social preference proximity to social 10
tolerance proximity, within a 5 meter radius of the focal individual). Samplings were 11
randomized throughout the day and thirty 10-min focal samplings (i.e. a total of five hours) 12
had been obtained per individual by the end of the observations. 13
In parallel, instantaneous samplings were collected every 15 minutes and provided 14
information on “positive” proximity patterns (using the same ethogram detailed in 15
Supplementary Material, Table S1). The scan was valid if, and only if, all the group members 16
were seen within one minute of beginning the scan sampling. Approximately 20 scans were 17
carried out per day to obtain 200 scans per group. 18
Proximity data were discarded from the dataset when aggressive behaviours were 19
recorded, to ensure that we only measured proximities as a proxy of affiliative relationships 20
(stability indicator). We decided to concentrate our analyses solely on a positive pattern of 21
proximities as a “positive index of welfare” because aggressive behaviours are rare in both 22
wild and captive environment (Nakamichi & Kato, 2001; Stokes, 2004). Moreover, additional 23
data collection for aggressive behaviours would have required all occurrences samplings, 24
which was not achievable with a single observer. The data collected from focal animal 25
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samplings (in terms of durations), and from the instantaneous samplings (in terms of 1
occurrences) were used to build proximity matrices of the “positive” patterns performed at 2
social preference, social tolerance, then finally general social proximities for each group (see 3
next paragraph). 4
Social network analysis 5
Social network analysis (SNA) required the collection of all dyadic proximity patterns in 6
a studied group. Observation matrices (at social preference, tolerance, and general proximity) 7
were built by considering the quotient recorded during the observations for each of the two 8
individuals, thus obtaining an average dyadic social proximity value. The sociality focal and 9
scan matrices for each group were compared using Dietz’ R matrix correlation tests (1 000 10
permutations in SOCPROG 2.8, see Supplementary Material, Table S2). The average R-11
correlation coefficients of the 11 groups were R=0.89, R=0.82, and R=0.77 for general social 12
proximity, social preference proximity and social tolerance proximity, respectively, and were 13
highly correlated (combined P-value < 0.0001; R-package CombinePValue). These 14
correlations confirm the validity of all data collected and the use of both matrices (built after 15
focal and scan observations) in the same way for the statistical analysis. 16
The indices of the matrices of associations were obtained with SOCPROG 2.8 17
software (Whitehead, 2009). The weighted networks of familial and bachelor groups are 18
represented as graphs via Gephi software (https://gephi.github.io) (see Supplementary 19
Material, Figures S1 to S10). We focused on the strength index for an individual, which is 20
equal to the sum of the total duration/occurrence of proximities with all group peers in our 21
study. Individuals with a high strength index have strong associations with others and/or have 22
many associates (Carter et al., 2013). By dividing the strength index of a chosen individual by 23
the number of group partners, we obtained what we called a personal sociality index (PSI). 24
This index thus determines both the activity budget time and social affinities by revealing 25
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“what the individual wants to do near which conspecifics". It is therefore an individual 1
indicator of cohesion. 2
Statistical Analyses 3
Analyses were performed to compare 27 JUV and ADO males. Amongst these males, 9 4
intact ADO males lived in bachelor groups and the remaining eighteen males lived in familial 5
groups: nine were castrated (5 JUV and 4 ADO) and nine were intact (5 JUV and 4 ADO) - 6
see details of immature males in Table 2. The data for Mapenzi (castrated ADO in the 7
Beauval group) and Nakouh (intact ADO in the Burgers zoo group) were excluded from all 8
tests after being identified as outlier values on the boxplot distribution for a number of 9
variables (see Figure S11 in Supplementary Material, and further details in the Discussion 10
section). We used tests to look for differences as a function of age classes, fertility status 11
(castrated vs. intact), and housing situation (familial or bachelor groups) for the following 12
variables: (1) PSI, (2) percentage of time spent in isolation (no conspecifics within a 5 meter 13
radius), (3) percentage of time spent in social play behaviours, (4) percentage of time spent in 14
social proximity with the silverback, (5) percentage of time spent in social proximity with the 15
mother, and (6) percentage of time spent in social proximity with adult females. Both social 16
preference and tolerance proximities were taken into account when testing the variables for 17
PSI and the percentage of time spent in proximity with the adult peers. We ran our analyses in 18
three steps: 19
Comparing variables with age. 20
First, Spearman rank correlation tests with permutations (Spearman test function in the R coin 21
package) were conducted to establish the “positive” social patterns of the captive immature 22
males through determined functions (fertility status and housing situation). 23
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Comparing variables specifically for adolescents. 1
In a second step, one-way analysis with permutation tests (perm.oneway.anova in the R-2
package wPerm) and pairwise permutation post-hoc tests were performed to compare the 3
mean as a percentage of time for the three categories of ADO males for variables 1 to 3 (intact 4
males living in bachelor groups, intact and castrated males living in familial groups). 5
Comparing variables specifically for immature males living in familial groups. 6
In a last step, permutation tests for independent samples (permTS in the R package perm) 7
were performed to look for any significant differences among the castrated and intact 8
immature males living in familial groups (variables (1) to (6) for the JUV age class, and 9
variables (4) to (6) for the ADO age class). Despite our small sample size, we decided to 10
exclude the data of the two outliers given that the high number of permutations strengthened 11
the results of our tests. 12
All the analyses run in R (version 3.4.2) were two-tailed and the probability of a type I error 13
was maintained at 0.05. All tests were performed with 9999 permutations. 14
Results 15
Matrices of scan associations were analysed to obtain the sociograms of the 11 groups 16
(Figure 1: Artis group example, see Supplementary Material for the other groups, Figures S1 17
to S10). 18
1) Personal social index (PSI) 19
The evolution of the personal social index PSI was compared to age for the three categories of 20
males using Spearman rank correlation tests with permutations. A negative correlation was 21
noted for intact males living in familial groups at social preference proximity (Fig. 2A) (rho=-22
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0.95, P=0.007) and at social tolerance proximity (Fig 2B) (rho=-0.88, P=0.015). No 1
correlation was found for castrated males living in familial groups at social preference 2
proximity (rho=-0.37, P=0.3), whereas a positive correlation was observed at social tolerance 3
proximity (rho=0.72, P= 0.043). No correlations were observed for the intact males living in 4
bachelor groups at both social preference (rho=0.13, P=0.704) and social tolerance proximity 5
(rho=0.19, P=0.586). Permutation tests in the two JUV categories (intact and castrated) living 6
in familial groups did not reveal any significant differences at social preference (P=0.373) or 7
social tolerance proximity (P=0.984). One-way analysis of the three ADO categories of 8
immature males did not reveal any significant differences at social preference proximity, with 9
a value of P=0.207. However, a trend of significant difference (P=0.085) was observed at 10
social tolerance proximity. Pairwise permutation tests revealed that the PSI at social tolerance 11
proximity for castrated ADO individuals living in familial groups was significantly higher 12
than that of intact ADO males living in the same context (Padjust=0.032). The other pairwise 13
comparisons reveal no differences (intact in familial groups – intact in bachelor groups: 14
Padjust=0.636; castrated in familial groups – intact in bachelor groups: Padjust=0.128). 15
2) Isolation time 16
Spearman rank correlation testing between the percentage of time budget spent in isolation 17
and the age of individuals indicated a positive correlation (rho=0.90, P=0.011) for intact 18
males living in familial groups (see FIG 3A). There were no correlations for castrated males 19
living in familial groups (rho=0.13, P=0.706) and for intact males living in bachelor groups 20
(rho=0.10, P=0.776). Permutation tests for the two JUV categories living in familial groups 21
did not reveal any significant differences in mean values for isolation (P=0.249). One-way 22
analysis for the three ADO categories of immatures males for the percentage of time spent 23
alone revealed significant differences (P<0.001), with significantly less isolation in ADO 24
castrated males (mean=15.15%±2.68) than in both intact ADO males living in familial groups 25
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(mean=30.61%±3.8) (Padjust=0.033) and intact ADO males living in bachelor groups 1
(mean=50.95%±6.08) (Padjust=0.009). Intact ADO males living in bachelor groups were also 2
more isolated than intact males living in familial groups (Padjust=0.029). 3
3) Social play 4
Spearman rank correlation testing between the percentage of time budget spent in social play 5
and the age of individuals (see FIG 3B) revealed a trend of negative correlation for intact 6
males living in bachelor groups (rho=-0.64, P=0.072) and for intact males living in familial 7
groups (rho=-0.60, P=0.08). However, no correlation was found for castrated males living in 8
familial groups (rho=-0.18, P=0.604). Permutation tests for the two JUV categories living in 9
familial groups did not reveal any significant differences in mean values for social play 10
(P=0.786). One-way analysis of the percentage of time budget spent in social play highlighted 11
significant differences between the three ADO categories of immatures males (P=0.016). 12
Post-hoc pairwise comparisons showed that castrated ADO males living in familial groups 13
tended to be significantly more involved in social play than intact ADO males living in 14
bachelor groups (Padjust=0.056), whereas no differences were found for the other pairwise 15
comparisons (intact ADO males in familial groups - intact ADO males in bachelor groups: 16
Padjust=0.965; intact ADO males in familial groups - castrated ADO males in familial groups: 17
Padjust=0.118). However, complementary permutation tests comparing the amount of social 18
play by males during juvenescence and adolescence highlighted that intact adolescents were 19
significantly less involved in play than intact juveniles (P=0.015), contrary to observations in 20
castrated immature males (P=0.73). 21
4) “Positive” pattern of proximity with the silverback proximity 22
The following results concern social variables that are only present in the familial 23
housing situation, and highlight the differences between the two fertility statuses (intact vs. 24
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15
castrated). Figure 4 compares the percentage of budget time used to perform positive 1
behaviour in the proximity of the silverback. The Spearman rank tests revealed a negative 2
correlation between age and the percentage of proximity with the silverback at social 3
preference proximity (Fig. 4A, rho=-0.85, P=0.017) and at social tolerance proximity (Fig. 4
4B, rho=-0.95, P=0.008) for the intact males. However, no correlations were found for the 5
castrated males at social preference proximity (Fig. 4A, rho=-0.15, P=0.666) or at social 6
tolerance proximity (Fig. 4B, rho=-0.32, P=0.370). Permutation tests comparing associated 7
means revealed that castrated ADO males performed significantly more positive behaviours at 8
social tolerance proximity with the silverback than the intact ADO males did (P=0.027). No 9
differences were found for the JUV and ADO males at social preference proximity (for JUV 10
P=0.421; for ADO P=0.543), or for the JUV males at social tolerance proximity (P=0.857). 11
5) “Positive” pattern of proximity with the mother 12
As some individuals did not have their mother in their group, it is important to note that 13
the sample size is smaller than the initial one for the tests on this variable (N=8 for intact 14
males (5 JUV + 3 ADO); N=7 for castrated males (4 JUV + 3 ADO)). For both categories 15
(intact and castrated), Spearman rank correlation tests revealed negative correlations at social 16
preference proximity when juveniles males were compared to older adolescents (FIG 5A, 17
intact: rho=-0.98, P=0.009; castrated: rho=-0.89, P=0.029). No correlations were found for the 18
same test at social tolerance proximity (FIG 5B, intact: rho=-0.57, P=0.120; castrated: 19
rho=0.29, P=0.484). The comparisons of associated means did not reveal any differences 20
between the two categories of males for JUV and ADO age classes (permutation tests at social 21
preference proximity for JUV P=0.413 and for ADO P=0.5; and at tolerance proximity for 22
JUV P=0.111and for ADO P=0.3). 23
6) “Positive” pattern of proximity with the adult females 24
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16
A ratio was used to allow comparisons between different numbers of females in each 1
group. Spearman rank correlation tests did not reveal any correlation at social preference 2
proximity when intact juveniles males were compared to older intact adolescents, and a trend 3
of significant positive correlation was observed for castrated males (FIG 6A, intact: rho=0.10, 4
P=0.813; castrated: rho=0.68, P=0.053). A positive correlation was observed for castrated 5
males at social tolerance proximity, whereas positive behaviours in the proximity of adult 6
females decreased with age for intact males (FIG 6B, intact: rho=-0.53, P=0.136; castrated: 7
rho=0.82, P=0.019). The permutation tests did not reveal any significant differences at social 8
preference proximity (for JUV P=0.532 and ADO P=0.257). Likewise, no difference was 9
observed for the JUV age-class (P=0.571) at social tolerance proximity. However, castrated 10
ADO males performed significantly more positive behaviours towards adult females than the 11
intact ADO males did (P=0.029). 12
Discussion 13
This is the first study to focus on the socialization process of immature male gorillas in 14
captivity, according to both the fertility status (castrated or intact) and the social composition 15
(familial or bachelor grouping). These comparisons between the three categories of immature 16
males, i.e. intact and castrated living in a familial group; and intact living in a bachelor group, 17
revealed significant differences according to the personal sociality index, the percentage of 18
time budget spent in isolation, and the percentage of time budget spent on social play. 19
The first finding is that the differences between the male categories from different age 20
classes only occurred within social tolerance proximity (between one to five meters). It was 21
not surprising that no differences were observed at social preference proximity (within one 22
metre of the focal contact) because unlike chimpanzees and bonobos, gorillas generally 23
perform few positive behaviours in the close proximity of a conspecific, as mentioned in a 24
number of studies (Chelluri et al, 2013; Furuichi & Ihobe, 1994). Secondly, in accordance 25
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17
with the history life trait already described for gorilla species, intact males living in familial 1
groups became less and less socially cohesive as they grew up (i.e. the personal sociality 2
index decreased significantly at both social preference and tolerance proximity). Our results 3
converged with those stating that spatial associations, proximity and affiliation decrease as the 4
frequency and intensity of aggression increases in both wild (Harcourt & Stewart, 1981; 5
Robbins et al., 2004; Watts & Pusey, 1993) and captive environments (Abelló et al., 2017; 6
Stoinski et al, 2004; Vermeer et al., 2014). This generates a progressive peripheralization until 7
the emigration (in the wild) or the transfer (human management in captivity) of the male from 8
the natal group. Additionally, maturation during adolescence is accompanied by intense 9
morphological changes in stature: maturing males increasingly differ from their younger 10
conspecifics in terms of body size and social skills. This leads to unbalanced power relations 11
which explain the increased spatial distance with the other immature members of the group, 12
and, in turn, a lower intragroup cohesiveness (i.e. a decrease in the sociality index for the 13
adolescence age class). Immature males housed in bachelor groups contrasted with those 14
housed in familial groups because their sociality index did not evolve significantly during 15
adolescence. Wild male mountain gorillas have been reported to live together for years in 16
unisex groups if they are not joined by females (Fossey, 1983; Yamagiwa, 1987a, 1987b). 17
Multimale groups are rare in western lowland gorillas (Magliocca et al, 1999; Parnell, 2002), 18
but an all-male structure was observed for long periods of between 13 months and 3 years in 19
observed groups that contained more than one immature or adult male (Gatti et al, 2004; 20
Robbins et al., 2004). Levrero and colleagues also reported wild western lowland gorilla 21
bachelor groups in 2006, but none of these groups were composed of several silverbacks. 22
Furthermore, strong affiliative relationships among males in a captive bachelor group are 23
most likely to occur when males are immature (Stoinski et al., 2004). It is therefore preferable 24
to transfer immature males at an early age if they are destined for life in a bachelor group, 25
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18
because socialization with other males is easier with younger animals (Abelló et al., 2017). 1
These different aspects, as well as the absence of competition for mating in captive bachelor 2
groups, could explain the stability of the sociality index for the adolescent bachelor males 3
studied. With the exception of the differences highlighted between the two housing situations 4
(familial and bachelor grouping), our results underline contrary types of social changes 5
according to the fertility status of individuals. Comparison of juvenescent and adolescent life 6
stages showed that while intact males are excluded from the familial group at adolescence, 7
castrated males significantly increased their intragroup cohesiveness at tolerance. Moreover, 8
analyses in the familial groups revealed significantly more cohesion in social bonds for 9
castrated adolescents compared to intact males of the same age class. 10
The results for isolation time are in concordance with our findings on the personal 11
sociality index. The intact adolescent males living in a familial group were significantly more 12
isolated than the castrated adolescent males, and, the intact adolescent males living in a 13
bachelor group spent significantly more time in isolation than both intact and castrated 14
adolescent males living in a familial group. Like in the wild, the “positive” or “negative” 15
reactions between males in a captive bachelor group are expected to be directly related to the 16
perceived affinity with a conspecific, but also to a possible threat of a specific male, reflecting 17
both the degree of vulnerability of the latter (his age and physical condition) and his relative 18
familiarity with the other males. Consequently, zoos that are designing an enclosure for a 19
bachelor group are advised to follow the recommendations made by Stoinski et al., in 2004(b) 20
and Coe et al. in 2009 to ensure that gorilla males can control how much space they are able 21
to put between themselves and conspecifics. Young silverback individuals were present in 22
two of the bachelor groups studied (Amneville group 2 and Loro Parque), and this factor 23
could explain the higher isolation rates observed for intact adolescent males in a bachelor 24
group. Also, time spent in isolation may simply be the expression of the individual’s personal 25
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19
desire to be alone. Similarly, the captive housing conditions of a familial group should be 1
carefully considered when anticipating the removal of intact males that have reached the end 2
of adolescence, due to the possible increase in conflicts with the silverback (personal 3
observations). Maturing intact adolescents tend to challenge their fathers (and conversely), 4
and this can cause social stress for all group members. The housing should provide enough 5
space for gorillas to avoid these conflicts, and be complex enough to provide safe escape 6
routes and isolation areas. In this respect, the different management strategies evaluated in 7
this study (familial and bachelor grouping) can permit individuals to avoid conflict, and thus 8
become a critical a reliable tool to improve the well-being of social species maintained in 9
captivity (Morgan & Tromborg, 2007). Given that the significantly higher share of isolation in 10
the time budget of intact males living in bachelor groups does not impact the personal 11
sociality index (i.e. there are no differences between intact males living in the different 12
housing situations), it is likely that male-male interactions are promoted in the unisex social 13
context. These findings suggest that gorillas have the possibility to selectively modify the 14
distribution of some typical patterns of their behavioural repertoire according to the housing 15
situation and the social composition of the group. This high level of behavioural flexibility 16
has been also highlighted in captivity by testing the crowding effect in the Apenheul gorilla 17
group (Cordoni & Palagi, 2007). The dynamic of the social networks emerging from social 18
relationships between members and the pattern of activity time budget are constantly 19
evolving, and therefore require a detailed follow-up to ensure optimal captivity welfare. Our 20
study protocol highlights that social network analysis is a useful tool to improve the 21
monitoring of the different management strategies used for animals in captivity. 22
Results for the involvement of the immature males in social play are in concordance with 23
the known life history traits for gorilla species. Whatever the housing situation, all intact 24
males tended to play significantly less from juvenility to adolescence, and even during 25
Page 21
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20
adolescence. This evolution is due to changes in time budgets during maturation (increased 1
foraging time as well as a growing interest in other social activities such as agonism and sex), 2
leading to an overall decline in play at the end of the juvenile period. Moreover, as for other 3
primate species such as the chimpanzee (Shimada & Sueur, 2014) and Japanese macaques 4
(Shimada & Sueur, 2018), it appears that social play mainly fulfils the function of 5
strengthening social bonds during juvenility, with a significant decrease during adolescence. 6
The results of Maestripieri and Ross’ study in 2004 were consistent with both motor training 7
and social skills hypotheses for captive gorillas aged from 0 to 5 years. Our results and those 8
of Maestripieri and Ross (2004) highlight the importance of considering “social 9
compatibilities” during the formation of bachelor groups. Like other primate species, 10
immature gorillas are expected to play and interact mostly with individuals that have 11
equivalent body size and social skills (Fagen, 1981; Fairbanks, 1993). This morphological 12
compatibility factor is a major concern for the formation and maintaining of all-male groups 13
in captivity. The absence of appropriate social partners is the major factor that could explain 14
the outlier data recorded for the castrated individual Mapenzi, housed in a familial group at 15
Beauval zoo (see Supplementary Material, Fig. S11). The same may apply to the outlier data 16
for Nakouh, an adolescent intact male in Burgers’ zoo (see Supplementary Material, Fig. 17
S11). An adult female from this institution gave birth on the 13th
June 2013 to twins, N’kato 18
and N’hasa. This event is very rare in gorillas and may explain the data recorded for Nakouh: 19
the presence of a new-born in a group induces a significant reduction in inter-individual 20
distance not only for characterized specific dyadic interactions (Nakamichi & Kato, 2001; 21
Stoinski et al, 2003) but also for general group cohesion (Kurtycz et al, 2014). Moreover, 22
there were no older immature conspecifics with whom Nakouh could interact. He did live 23
with three younger males during his socialization process. Nakouh’s socialization process 24
may have been delayed by this social imbalance. However, complementary tests comparing 25
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21
the share of social play between juvenile and adolescent age classes underline that castrated 1
individuals do not decrease their involvement in social play during these two life stages, 2
unlike the intact males. The combined results on the three variables described (personal 3
sociality index, isolation and share of social play in time budget) highlight that captive 4
western lowland gorillas are socially flexible, and confirm that maturing males adapt well to 5
the bachelor management strategy that has been implemented for over three decades. Indeed, 6
the "positive" interactions prioritised by males maintain social cohesion despite a greater 7
share of isolation in the activity budget time, suggesting that maturing males are adapting well 8
to bachelor group housing. Finally, the different behavioural patterns presented in our study 9
suggest that castration has a positive impact on the intra-group cohesiveness of the individuals 10
during juvenescence and adolescence. 11
While gorilla familial groups are mainly based on adult male-female bonds (Harcourt & 12
Stewart, 2007), relationships between the silverback and its offspring play a significant role in 13
group structure. As already shown in different studies, the close bonds between the adult male 14
and the immature males (Rosenbaum et al, 2016; Stewart, 2001; Yamagiwa, 1983) are best 15
explained as paternal care (protection and tolerance of proximity) rather than a significant 16
investment in their offspring (resting in contact, grooming, play) (Rosenbaum et al, 2011). 17
The “positive” behaviours that intact immature males performed at preference proximity of 18
the silverback and the mother decreased significantly when they reached maturity. This was 19
also the case at tolerance proximity with the silverback. Conversely, in accordance with our 20
results on the personal sociality index, castrated males keep strong social bonds with the 21
silverback and the adult females when they reach adolescence life stage (i.e. a significant 22
increase at tolerance proximity during maturation). This increase in proximity and interactions 23
might be explained by the fact that conspecifics perceive changes induced by castration that 24
could be visual, auditory, olfactory, and/or behavioural (Caillaud et al., 2008; Masi & Bouret, 25
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22
2015). Our study therefore highlights not only behavioural changes for castrated individuals, 1
but also a different perception of the latter by their group peers. Although our study did not 2
address this issue, our results suggest an effect of castration on the development of social 3
bonds. The castration induces a cancellation of the growth associated with the first stage of 4
androgen increase during adolescence (Stoinski et al., 2002) (see Supplementary Material, 5
Fig. S12), and could for example increase “the social compatibilities” between the 6
developmentally staggered individuals that compose the group. The behavioural and 7
morphological modifications observed may improve group cohesiveness, in accordance with 8
the social and motor skills hypotheses (Baldwin & Baldwin, 1974; Byers, 1998). 9
As physical, social or psychological alterations are often associated with subtle changes 10
in behaviour, our behavioural monitoring data can be beneficial to many areas of gorilla 11
husbandry. The collaboration of European zoos in this study has ensured a low number of 12
biases due to care routines, diet recommendations and environmental standards that all follow 13
the same set of guidelines recommended by the EEP (for details see Abelló et al., 2017). We 14
acknowledge that caution must be taken when making our conclusions, as the individuals 15
involved were observed for just one month of their development. For this reason, future 16
research should be carried out over the long-term to gain a more detailed knowledge of the 17
social and physiological development of castrated males in familial groups and intact males in 18
bachelor groups. 19
Conclusion and perspectives 20
Our study suggests that the housing of castrated surplus males in familial groups is a 21
feasible alternative strategy for positive socio-behavioural management during the maturation 22
of gorilla males. Indeed, our results highlight that castrated adolescents are significantly more 23
cohesive in their native group than their intact counterparts. Furthermore, our results 24
comparing intact immature males living in familial and bachelor contexts are in concordance 25
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23
with those of all the previous studies focusing on captive gorilla bachelor groups. These 1
results strengthen the efforts made by the Gorilla Eaza Ex-situ Programme (GEEP) to 2
improve the different housing management strategies designed to solve the growing problem 3
of surplus male gorillas in captivity. We recommend avoiding the castration of immature 4
males that have no other immature male peers in their group (as seen in the case of Mapenzi, a 5
castrated adolescent male excluded as outlier data from our analyses). Immature males that 6
are transferred into bachelor groups should be pair-generational individuals that share the 7
same developmentally staggered stages, as described by the motor-training hypothesis and the 8
social-relationship hypothesis of play (Maestripieri & Ross, 2004) and social development in 9
general (this study). Other factors such as enclosure size, differences in facility design 10
features, effects of spatial crowding, group size and daily care routine could all affect the 11
proximity between gorillas group members and their behaviour (Coe et al., 2009; Kuhar, 12
2008; Ross, Calcutt, Schapiro, & Hau, 2011). It is unlikely that all of these factors explain all 13
of the variation in social dynamics, it will nevertheless be essential to include these covariates 14
in the next studies. Moreover, future studies are necessary to investigate whether castrated 15
males have behavioural similarities with females, and understanding how castration 16
influences physical and hormonal development can help us to better understand the long-term 17
effects of this contraceptive method on the social dynamics of the group. Our results should 18
be complemented with a further study comparing the networks of “negative” proximity 19
pattern in the same way as we did here for “positive” proximity. Finally, the long-term 20
monitoring of castrated males is necessary, especially from the young silverback age-class 21
until adulthood, to ascertain whether the use of castration as an additional socio-behavioural 22
management strategy is consistent over time and meets the welfare criteria for maintaining 23
this species in captivity. 24
Acknowledgements 25
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24
We thank Frank Rietkerk, Neil Bemment, Maria Teresa Abelló, Sonya Hill and their 1
colleagues of the Gorilla EEP Committee for their support and commitment to the gorillas in 2
their care. We would also like to thank the different zoos, which were all very helpful and 3
cooperative in providing information and invitations: Parc Zoologique d’Amneville; Artis 4
Amsterdam Royal Zoo; Apenheul; Zooparc de Beauval; Burgers’ Zoo; Chessington World of 5
Adventures; GaïaPark Zoo; Loro Parque; and La Vallée des Singes, and extend our thanks to 6
all the animal keepers involved. We are grateful to all the institutions and/or their associations 7
that have funded this study: Antwerpen Zoo, Apenheul, Basel Zoo, Barcelona Zoo, Zooparc 8
de Beauval and Beauval Nature, Safaripark Beekse Bergen, La Boissière du Doré, Dublin 9
Zoo, Bioparc Fuengirola, Gaïazoo, Erlebniz zoo Hannover, Heidelberg Zoo, Krefeld Zoo, 10
Longleat Safari Park, Madrid Zoo, Münchner Tierpark Hellabrunn, Nuremberg Zoo, Rostock 11
Zoo, Wilhelma Stuttgart, Taipei Zoo, Der Grüne Zoo Wuppertal, La Vallée des Singes, and 12
Zurich Zoo. We also thank the Zooparc de Beauval and Cindy Tuijtelaars for the photographs 13
illustrating Figure S12. 14
15
16
References: 17
Abelló, M. T., Bemment, N., & Rietkerk, F. (2017). EAZA BEST PRACTICE GUIDELINES 18
Great Ape Taxon Advisory Group GORILLA ( Gorilla gorilla gorilla ) (2nd ed.). 19
Barcelona: Barcelona Zoo, and Amsterdam, EAZA Executive Office. 20
Baldwin, J. D., & Baldwin, J. I. (1974). Exploration and social play in squirrel monkeys 21
(Saimiri). American Zoologist, 14(1), 303–315. https://doi.org/10.1093/icb/14.1.303 22
Breuer, T., Hockemba, M. B. N., Olejniczak, C., Parnell, R. J., & Stokes, E. J. (2009). 23
Physical maturation, life-history classes and age estimates of free-ranging western 24
Page 26
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65
25
gorillas - Insights from Mbeli Bai, Republic of Congo. American Journal of 1
Primatology, 71(2), 106–119. https://doi.org/10.1002/ajp.20628 2
Byers, J. A. (John A. (1998). Biological effects of locomotor play: General or specific? In 3
Animal play : evolutionary, comparative, and ecological prespectives (p. 274). 4
Cambridge University Press. 5
Caillaud, D., Levréro, F., Gatti, S., Ménard, N., & Raymond, M. (2008). Influence of male 6
morphology on male mating status and behavior during interunit encounters in western 7
lowland gorillas. American Journal of Physical Anthropology, 135(4), 379–388. 8
https://doi.org/10.1002/ajpa.20754 9
Carter, K. D., Brand, R., Carter, J. K., Shorrocks, B., & Goldizen, A. W. (2013). Social 10
networks, long-term associations and age-related sociability of wild giraffes. Animal 11
Behaviour, 86(5), 901–910. https://doi.org/10.1016/j.anbehav.2013.08.002 12
Chelluri, G. I., Ross, S. R., & Wagner, K. E. (2013). Behavioral correlates and welfare 13
implications of informal interactions between caretakers and zoo-housed chimpanzees 14
and gorillas. Applied Animal Behaviour Science, 147(3–4), 306–315. 15
https://doi.org/10.1016/j.applanim.2012.06.008 16
Clark, F. E. (2011). Space to choose: Network analysis of social preferences in a captive 17
chimpanzee community, and implications for management. American Journal of 18
Primatology, 73(8), 748–757. https://doi.org/10.1002/ajp.20903 19
Coe, J. C., Scott, D., & Lukas, K. E. (2009). Facility design for bachelor gorilla groups. Zoo 20
Biology, 28(2), 144–162. https://doi.org/10.1002/zoo.20233 21
Cordoni, G., & Palagi, E. (2007). Response of captive lowland gorillas (Gorilla gorilla gorilla) 22
to different housing conditions: Testing the aggression-density and coping models. 23
Journal of Comparative Psychology, 121(2), 171–180. https://doi.org/10.1037/0735-24
7036.121.2.171 25
Page 27
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65
26
Fagen, R. (1981). Animal play behavior. Oxford University Press. 1
Fairbanks, L. A. (1993). Juvenile vervet monkeys: establishing relationships and practicing 2
skills for the future. In Juvenile primates: life history, development, and behavior. (p. 3
428). University of Chicago Press. 4
Fossey, D. (1983). Gorillas in the Mist. (Hodder & Stoughton, Eds.). London: Hodder & 5
Stoughton. 6
Furuichi, T., & Ihobe, H. (1994). Variation in male relationships in bonobos and 7
chimpanzees. Behaviour, 130((3-4)). 8
https://doi.org/https://doi.org/10.1163/156853994X00532 9
Gatti, S., Levréro, F., Ménard, N., & Gautierhion, A. (2004). Population and group structure 10
of western Lowland Gorillas (Gorilla gorilla gorilla) at Lokoué, Republic of Congo. 11
American Journal of Primatology, 63(3), 111–123. https://doi.org/10.1002/ajp.20045 12
Gold, K. C., & Maple, T. L. (1994). Personality-Assessment in the Gorilla and Its Utility as a 13
Management Tool. Zoo Biology, 13(5), 509–522. 14
https://doi.org/10.1002/zoo.1430130513 15
Harcourt, A. H. (1978). Strategies of Emigration and Transfer by Primates, with Particular 16
Reference to Gorillas. Zeitschrift Für Tierpsychologie, 48(4), 401–420. 17
https://doi.org/10.1111/j.1439-0310.1978.tb00267.x 18
Harcourt, A. H., & Stewart, K. J. (1981). Gorilla male relationships: Can differences during 19
immaturity lead to contrasting reproductive tactics in adulthood? Animal Behaviour, 20
29(1), 206–210. https://doi.org/10.1016/S0003-3472(81)80167-4 21
Harcourt, A. H., & Stewart, K. J. (2007). Gorilla society: What we know and don’t know. 22
Evolutionary Anthropology, 16(4), 147–158. https://doi.org/10.1002/evan.20142 23
Harcourt, A., & Stewart, K. (1977). Apes, sex, and societies. New Scientist., 76, 160–162. 24
Johnstone-Scott, R. A. (1988). Johnstone-Scott, R. A. The potential for establishing bachelor 25
Page 28
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65
27
groups of western lowland gorillas (Gorilla gorilla gorilla). Dodo, 25, 60–66. 1
Kanngiesser, P., Sueur, C., Riedl, K., Grossmann, J., & Call, J. (2011). Grooming network 2
cohesion and the role of individuals in a captive chimpanzee group. American Journal of 3
Primatology, 73(8), 758–767. https://doi.org/10.1002/ajp.20914 4
Kasper, C., & Voelkl, B. (2009). A social network analysis of primate groups. Primates, 5
50(4), 343–356. https://doi.org/10.1007/s10329-009-0153-2 6
Kuhar, C. W. (2008). Group differences in captive gorillas’ reaction to large crowds. Applied 7
Animal Behaviour Science, 110(3–4), 377–385. 8
https://doi.org/10.1016/j.applanim.2007.04.011 9
Kuhar, C. W., Stoinski, T. S., Lukas, K. E., & Maple, T. L. (2006). Gorilla Behavior Index 10
revisited: Age, housing and behavior. Applied Animal Behaviour Science, 96(3–4), 315–11
326. https://doi.org/10.1016/j.applanim.2005.06.004 12
Kurtycz, L. M., Shender, M. A., & Ross, S. R. (2014). The birth of an infant decreases group 13
spacing in a zoo-housed lowland gorilla group (Gorilla gorilla gorilla). Zoo Biology, 14
33(5), 471–474. https://doi.org/10.1002/zoo.21156 15
Leeds, A., Boyer, D., Ross, S. R., & Lukas, K. E. (2015). The effects of group type and young 16
silverbacks on wounding rates in western lowland gorilla (Gorilla gorilla gorilla) groups 17
in North American zoos. Zoo Biology, 34(4), 296–304. 18
https://doi.org/10.1002/zoo.21218 19
Less, E. H., Kuhar, C. W., & Lukas, K. E. (2013). Assessing the prevalence and 20
characteristics of hair-plucking behaviour in captive western lowland gorillas (Gorilla 21
gorilla gorilla). Animal Welfare, 22(2), 175–183. 22
https://doi.org/10.7120/09627286.22.2.175 23
Levréro, F., Gatti, S., Ménard, N., Petit, E., Caillaud, D., & Gautierhion, A. (2006). Living in 24
Nonbreeding Groups: An Alternative Strategy for Maturing Gorillas. American Journal 25
Page 29
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65
28
of Primatology, 68(3), 275.291. https://doi.org/10.1002/ajp.20223 1
Maestripieri, D., & Ross, S. R. (2004). Sex Differences in Play among Western Lowland 2
Gorilla (Gorilla gorilla gorilla) Infants: Implications for Adult Behavior and Social 3
Structure. American Journal of Physical Anthropology, 123(1), 52–61. 4
https://doi.org/10.1002/ajpa.10295 5
Magliocca, F., Querouil, S., & Gautier-Hion, A. (1999). Population structure and group 6
composition of western lowland gorillas in north-western Republic of Congo. American 7
Journal of Primatology, 48(1), 1–14. https://doi.org/10.1002/(SICI)1098-8
2345(1999)48:1<1::AID-AJP1>3.0.CO;2-2 9
Masi, S., & Bouret, S. (2015). Odor signals in wild western lowland gorillas: An involuntary 10
and extra-group communication hypothesis. Physiology and Behavior, 145, 123–126. 11
https://doi.org/10.1016/j.physbeh.2015.03.022 12
McCowan, B., Anderson, K., Heagarty, A., & Cameron, A. (2008). Utility of social network 13
analysis for primate behavioral management and well-being. Applied Animal Behaviour 14
Science, 109(2–4), 396–405. https://doi.org/10.1016/j.applanim.2007.02.009 15
Morgan, K. N., & Tromborg, C. T. (2007). Sources of stress in captivity. Applied Animal 16
Behaviour Science, 102(3–4), 262–302. https://doi.org/10.1016/j.applanim.2006.05.032 17
Nakamichi, M., & Kato, E. (2001). Long-term proximity, relationships in a captive social 18
group of western lowland gorillas (Gorilla gorilla gorilla). Zoo Biology, 20(3), 197–209. 19
https://doi.org/10.1002/zoo.1020 20
Ogden, J., & Wharton, D. (1997). Management of Gorillas in Captivity. Wildlife 21
Conservation, 294. 22
Parnell, R. J. (2002). Group size and structure in western lowland gorillas (Gorilla gorilla 23
gorilla) at Mbeli Bai, Republic of Congo. American Journal of Primatology, 56(4), 193–24
206. https://doi.org/10.1002/ajp.1074 25
Page 30
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65
29
Pullen, P. K. (2005). Preliminary comparisons of male/male interactions within bachelor and 1
breeding groups of western lowland gorillas (Gorilla gorilla gorilla). Applied Animal 2
Behaviour Science, 90(2), 143–153. https://doi.org/10.1016/j.applanim.2004.08.016 3
Richards, B., Noble, P. L., Woodward, R. A., Winslow, J. T., & Weickert, C. S. (2009). 4
Gonadectomy Negatively Impacts Social Behavior of Adolescent Male Primates. 5
Hormones and Behavior, 56(1), 140–148. https://doi.org/10.1016/j.jmb.2008.10.054. 6
Robbins, M. M. (2007). Gorillas-diversity in ecology and behavior. Primates in Perspective, 7
305–321. 8
Robbins, M. M., Bermejo, M., Cipolletta, C., Magliocca, F., Parnell, R. J., & Stokes, E. 9
(2004). Social structure and life-history patterns in western gorillas (Gorilla gorilla 10
gorilla). American Journal of Primatology, 64(2), 145–159. 11
https://doi.org/10.1002/ajp.20069 12
Rose, P. E., & Croft, D. P. (2015). The potential of social network analysis as a tool for the 13
management of zoo animals. Animal Welfare, 24(2), 123–138. 14
https://doi.org/10.7120/09627286.24.2.123 15
Rosenbaum, S., Maldonado-Chaparro, A. A., & Stoinski, T. S. (2016). Group structure 16
predicts variation in proximity relationships between male–female and male–infant pairs 17
of mountain gorillas (Gorilla beringei beringei). Primates, 57(1), 17–28. 18
https://doi.org/10.1007/s10329-015-0490-2 19
Rosenbaum, S., Silk, J. B., & Stoinski, T. S. (2011). Male-immature relationships in multi-20
male groups of mountain gorillas (Gorilla beringei beringei). American Journal of 21
Primatology, 73(4), 356–365. https://doi.org/10.1002/ajp.20905 22
Ross, S. R., Calcutt, S., Schapiro, S. J., & Hau, J. (2011). Space use selectivity by 23
chimpanzees and gorillas in an indoor-outdoor enclosure. American Journal of 24
Primatology, 73(2), 197–208. https://doi.org/10.1002/ajp.20891 25
Page 31
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65
30
Shimada, M., & Sueur, C. (2014). The Importance of Social Play Network for Infant or 1
Juvenile Wild Chimpanzees at Mahale Mountains National Park , Tanzania. American 2
Journal of Primatology, 76(11), 1025–1036. 3
https://doi.org/https://doi.org/10.1002/ajp.22289 4
Shimada, M., & Sueur, C. (2018). Social play among juvenile wild Japanese macaques ( 5
Macaca fuscata ) strengthens their social bonds. American Journal of Primatology, 6
80(1). https://doi.org/10.1002/ajp.22728 7
Stewart, K. J. (2001). Social relationships of immature gorillas and silverbacks. In Mountain 8
gorillas : three decades of research at Karisoke. Cambridge University Press. 9
Stoinski, T. S., Czekala, N., Lukas, K. E., & Maple, T. L. (2002). Urinary androgen and 10
corticoid levels in captive, male western lowland gorillas (Gorilla g. gorilla): Age- and 11
social group-related differences. American Journal of Primatology, 56(2), 73–87. 12
https://doi.org/10.1002/ajp.1065 13
Stoinski, T. S., Hoff, M. P., & Maple, T. L. (2001). Habitat Use and Structural Preferences of 14
Captive Western Lowland Gorillas ( Gorilla gorilla gorilla ): Effects of Environmental 15
and Social Variables, 22(3), 431–448. https://doi.org/10.1023/A:1010707712728 16
Stoinski, T. S., Hoff, M. P., & Maple, T. L. (2003). Proximity Patterns of Female Western 17
Lowland Gorillas (Gorilla gorilla gorilla) during the Six Months after Parturition. 18
American Journal of Primatology, 61(2), 61–72. https://doi.org/10.1002/ajp.10110 19
Stoinski, T. S., Kuhar, C. W., Lukas, K. E., & Maple, T. L. (2004). Social Dynamics of 20
Captive Western Lowland Gorillas Living in All-Malegroups. Behaviour, 141, 169–195. 21
https://doi.org/10.1163/156853904322890807 22
Stoinski, T. S., Lukas, K. E., & Kuhar, C. W. (2013). Effects of age and group type on social 23
behaviour of male western gorillas (gorilla gorilla gorilla) in North American zoos. 24
Applied Animal Behaviour Science, 147(3–4), 316–323. 25
Page 32
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65
31
https://doi.org/10.1016/j.applanim.2013.07.003 1
Stoinski, T. S., Lukas, K. E., Kuhar, C. W., & Maple, T. L. (2004). Factors influencing the 2
formation and maintenance of all-male gorilla groups in captivity. Zoo Biology, 23(3), 3
189–203. https://doi.org/10.1002/zoo.20005 4
Stokes, E. J. (2004). Within-group social relationships among females and adult males in wild 5
western lowland gorillas (Gorilla gorilla gorilla). American Journal of Primatology, 6
64(2), 233–246. https://doi.org/10.1002/ajp.20074 7
Strong, V., Baiker, K., Brennan, M. L., Redrobe, S., Rietkerk, F., Cobb, M., & White, K. 8
(2017). A retrospective review of western lowland gorilla ( GORILLA GORILLA 9
GORILLA ) mortality in European zoologic collections between 2004 and 2014. Journal 10
of Zoo and Wildlife Medicine, 48(2), 277–286. https://doi.org/10.1638/2016-0132R.1 11
Sueur, C., Jacobs, A., Amblard, F., Petit, O., & King, A. J. (2011). How can social network 12
analysis improve the study of primate behavior? American Journal of Primatology, 13
73(8), 703–719. https://doi.org/10.1002/ajp.20915 14
Sueur, C., & Pelé, M. (2015). Utilisation de l’analyse des réseaux sociaux dans la gestion des 15
animaux maintenus en captivité. Analyse des réseaux sociaux appliquée à l’éthologie et 16
à l’écologie. Editions Matériologiques, Paris, 445-468. 17
Vermeer, & Devreese. (2015). Birth sex ratio, infant mortality and rearing type in captive 18
western lowland gorillas. Journal of Zoo and Aquarium Research, 3(1), 6. 19
https://doi.org/10.1159/000156511 20
Vermeer, J., Abelló, M. T., & Holtkötter, M. (2014). Progress in the Western lowland gorilla 21
Gorilla gorilla gorilla European Endangered Species Programme: a review of the 22
decade 2002-2011. International Zoo Yearbook, 48(1), 234–249. 23
https://doi.org/10.1111/izy.12027 24
Watters, J. V, Margulis, Ã. S. W., & Atsalis, S. (2009). Behavioral Monitoring in Zoos and 25
Page 33
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65
32
Aquariums : A Tool for Guiding Husbandry and Directing Research, 48(May 2008), 35–1
48. https://doi.org/10.1002/zoo.20207 2
Watts, D., & Pusey, A. (1993). Behavior of juvenile and adolescent great apes. In Juvenile 3
Primates: Life History, Developement and Behavior (pp. 148–167). 4
https://doi.org/10.1017/CBO9781107415324.004 5
Watts, E., & Meder, A. (1996). Introduction and socialization techniques for primates. Wild 6
mammals in captivity : principles and techniques. University of Chicago Press. Retrieved 7
from https://ci.nii.ac.jp/naid/10027270430/ 8
Whitehead, H. (2009). SOCPROG programs: Analysing animal social structures. Behavioral 9
Ecology and Sociobiology, 63(5), 765–778. https://doi.org/10.1007/s00265-008-0697-y 10
Yamagiwa, J. (1983). Diachronic changes in two eastern lowland gorilla groups (Gorilla 11
gorilla graueri) in the Mt. Kahuzi Region, Zaïre. Primates, 24(2), 174–183. 12
https://doi.org/10.1007/BF02381080 13
Yamagiwa, J. (1987a). Intra- and inter-group interactions of an all-male group of virunga 14
mountain gorillas (Gorilla gorilla beringei). Primates, 28(1), 1–30. 15
https://doi.org/10.1007/BF02382180 16
Yamagiwa, J. (1987b). Male life history and the social structure of wild mountain gorillas 17
(Gorilla gorilla beringei). In Evolution and coadaptation in biotic communities (pp. 31–18
51). University of Tokyo Press. 19
Table legends 20
Table 1: Composition details of the familial and bachelor groups observed. FSC= familial 21
social context; BSC= bachelor social context. The two grey columns highlight the subjects for 22
whom data are retained for analysis and interpretation in this study (detailed in Table 2) 23
Institutions
Type
of
group
period of
observation
(month/year)
Number
of
animals
Adults (A)
Young
Silverback
(YSB)
Adolescent
(ADO)
[Intact/Castrated]
Juveniles (JUV)
[Intact/Castrated]
Infants
(INF)
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>18y
>10y 12-18y 6-12y
6-
10y 3-6y 3-6y
<3y
<3y
Artis FSC 04/2016 10 1 3 0 2 [2/0] 0 3 [2/1] 0 1 0
Apenheul FSC 07/2016 14 1 5 0 2 [2/0] 1 2 [1/1] 3 0 0
Beauval FSC 05/2016 13 1 4 0 1 [0/1] 2 0 3 2 0
Burgers'zoo FSC 08/2016 12 1 4 0 1 [1/0] 1 2 [2/0] 1 1 1
Chessington FSC 09/2016 8 1 4 0 1 [0/1] 0 1 [0/1] 1 0 0
Gaïazoo FSC 06/2016 9 1 3 0 2 [0/2] 0 1 [0/1] 0 1 1
La Vallée
des Singes
FSC 09/2016 9 1 4 0 1 [0/1] 0 1 [0/1] 1 1 0
Amneville
group 1
(G1)
BSC 04/2017 3 1 - 0 2 - - - - -
Amneville
group 2
(G2)
BSC 04/2017 5 1 - 2 2 - - - - -
Beauval BSC 05/2016 5 1 - 0 4 - - - - -
Loro
parque
BSC 03/2017 5 3 - 1 1 - - - - -
Total - 10 months 93 13 27 3 19 [14/5] 4 10 [5/5] 9 6 2
1
Table 2: Details concerning the immature males studied in FSC (familial groups) and BSC 2
(bachelor groups). Among the 29 subjects, the two grey individuals were excluded as outliers. 3
Name of
the
individual
Institution Sexual
status Birth
Social
context
Age during
observation
(years)
Age class
N'KATO Burgers'zoo intact 13/06/2013 FSC 3.2
Juveniles
(JUV)
NUKTA Burgers'zoo intact 25/03/2013 FSC 3.4
AYO Gaïazoo intact 31/12/2012 FSC 3.5
DOULI Artis intact 27/02/2012 FSC 4.1
MZUNGU Apenheul intact 26/06/2011 FSC 5.1
NAKOUH Burgers'zoo intact 04/11/2009 FSC 6.9
Adolescents
(ADO)
DAYO Artis intact 18/06/2008 FSC 7.9
WIMBE Apenheul intact 12/04/2008 FSC 8.3
MAPASA Apenheul intact 15/10/2007 FSC 8.8
SHOMARI Artis intact 12/07/2007 FSC 8.8
KAJOLU Beauval intact 08/12/2009 BSC 6.5
UPALA Amneville G2 intact 27/05/2008 BSC 9.0
UBONGO Loro parque intact 06/01/2008 BSC 9.3
BANJOKO Beauval intact 16/12/2006 BSC 9.5
SADIKI Beauval intact 10/10/2006 BSC 9.7
MONZA Amneville G2 intact 02/09/2007 BSC 9.7
AKIKI Amneville G1 intact 04/04/2007 BSC 10.2
N'GORO Amneville G1 intact 25/08/2006 BSC 10.8
KUMI Beauval intact 20/08/2004 BSC 11.9
JABARI Apenheul castrated 22/12/2012 FSC 3.6
Juveniles
(JUV)
SHAMBE Artis castrated 04/09/2011 FSC 4.6
MWANA Chessington castrated 23/02/2012 FSC 4.6
BEMBOSI Artis castrated 31/05/2011 FSC 4.9
MAWETE La Vallée des Singes castrated 20/11/2011 FSC 5.0
MAPENZI Beauval castrated 14/04/2010 FSC 6.2 Adolescents
(ADO) MOSI Gaïazoo castrated 10/02/2010 FSC 6.4
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34
MBULA Chessington castrated 10/03/2009 FSC 7.6
DJOMO La Vallée des Singes castrated 16/09/2008 FSC 8.2
LOANGO Gaïazoo castrated 23/12/2004 FSC 11.6
Figure legends 1
Fig 1: Weighted graphs of positive sociality scan network for the Artis group at (A) GSP 2
(social general proximity), (B) SPP (social preference proximity), and (C) STP (social 3
tolerance proximity). A specific size is assigned for each node (representing one individual). 4
This size is derived from the entry in the social proximity matrices indicating the strength of 5
the social bonds (the frequency of positive behaviours performed at GSP, SPP, or STP 6
proximity within all dyads) (Kasper & Voelkl, 2009). On these circular representations, node 7
sizes are ordered by ascending order of strength index. The thickness of the links between two 8
nodes represents the amount of positive social interactions recorded. The age class of each 9
individual, i.e. adult (A), adolescent (ADO), juvenile (JUV), and infant (INF), is indicated 10
after the name of the individual in the circle. The colours inside the circles represent the sex 11
of the individual: white for females, dark grey for males, and light grey for castrated males. 12
Fig 2: Changes in strength ratio (=PSI, variable 1) with age for the three categories of 13
immature male (intact and castrated males living in familial group (FSC), and intact males 14
living in bachelor groups (BSC) at (A) social preference proximity (SPP) and (B) social 15
tolerance proximity (STP). LTC indicates linear trend curve. 16
Fig 3: Changes in percentage of time budget spent in isolation (variable 2, 3A) with age for 17
the three categories of immature males (intact and castrated males living in familial groups 18
(FSC) and intact males living in bachelor groups (BSC)) and changes in the percentage of 19
time budget dedicated to social play with age for the same individuals (variable 3, 3B). LTC 20
indicates linear trend curve. 21
Fig 4: Changes in percentage of time budget spent in proximity with the silverback with age 22
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35
for the immature males (intact and castrated) (variable 4) living in familial groups (FSC), at 1
social preference proximity (SPP) (4A) and at social tolerance proximity (STP) (4B). LTC 2
indicates linear trend curve. 3
Fig 5: Changes in percentage of time budget spent in proximity with the mother (variable 5) 4
with age for immature males (intact and castrated) living in familial groups (FSC), at social 5
preference proximity (SPP) (5A) and at social tolerance proximity (STP) (5B). LTC indicates 6
linear trend curve. 7
Fig 6: Changes in percentage of time budget spent in proximity with adult females (variable 8
6) with age for immature males (intact and castrated) living in familial groups (FSC) at social 9
preference proximity (SPP) (6A) and at social tolerance proximity (STP) (6B). LTC indicates 10
linear trend curve. 11
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Figure 3Click here to download high resolution image
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Figure 5Click here to download high resolution image
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Figure 6Click here to download high resolution image